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Durability Assessment of Diesel Cold Start Concept (dCSC™) Technologies
- Hai-Ying Chen - Johnson Matthey Inc. ,
- Donna Liu - Johnson Matthey Inc. ,
- Erich Weigert - Johnson Matthey Inc. ,
- Lasitha Cumaranatunge - Johnson Matthey Inc. ,
- Kenneth Camm - Johnson Matthey Inc. ,
- Patrick Bannon - Johnson Matthey Inc. ,
- Julian Cox - Johnson Matthey Inc. ,
- Louise Arnold - Johnson Matthey Inc.
ISSN: 1946-3936, e-ISSN: 1946-3944
Published March 28, 2017 by SAE International in United States
Citation: Chen, H., Liu, D., Weigert, E., Cumaranatunge, L. et al., "Durability Assessment of Diesel Cold Start Concept (dCSC™) Technologies," SAE Int. J. Engines 10(4):1713-1721, 2017, https://doi.org/10.4271/2017-01-0955.
The phase-in of US EPA Tier 3 and California LEV III emission standards require further reduction of tailpipe criteria pollutants from automobiles. At the same time, the mandate for reducing Green House Gas (GHG) emissions continuously lowers the exhaust temperature. Both regulations pose significant challenges to emission control catalyst technologies, especially for cold start emissions. The recently developed diesel cold start concept technology (dCSC™) shows promising results. It stores NOx and HC during the cold start period until the downstream catalytic components reach their operating temperatures, when the stored NOx/HC are subsequently released and converted. The technology also has oxidation functions built in and acts as a diesel oxidation catalyst under normal operating conditions. In a US DOE funded project, the diesel cold start concept technology enabled a high fuel efficiency vehicle to achieve emissions targets well below the SULEV30 emission standards.
In this study, detailed lab assessments of a development diesel cold start concept catalyst were carried out with emphasis on its long-term durability. The catalyst exhibits high NOx/HC storage capacities with high trapping efficiency in the temperature range of 80 to 200 °C. The majority of NOx storage sites can be regenerated at temperatures above 250 °C. The catalyst is thermally durable after 750 °C/100 h/10% H2O hydrothermal aging, although a noticeable decline of NOx storage capacity is observed after 10 hours aging at 850 °C, or after exposure to a rich atmosphere. The catalyst also has good sulfur tolerance, maintaining high NOx storage capacity even after a 2 g S/L catalyst of sulfur exposure. The long-term durability of the catalyst to hydrothermal aging and to repetitive sulfation/desulfation cyclic aging is also demonstrated on engine/vehicle evaluations. An engine aged catalyst that represents its end of useful life shows clear advantages for cold start NOx/CO/HC emission control on a light-duty diesel truck.